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llvm-mirror/include/llvm/Support/BinaryStreamArray.h
Nicolás Alvarez 0bad578cf3 [docs] Fix doxygen comments wrongly attached to the llvm namespace
Looking at the Doxygen-generated documentation for the llvm namespace
currently shows all sorts of random comments from different parts of the
codebase. These are mostly caused by:

- File doc comments that aren't marked with \file, so they're attached to
  the next declaration, which is usually "namespace llvm {".
- Class doc comments placed before the namespace rather than before the
  class.
- Code comments before the namespace that (in my opinion) shouldn't be
  extracted by doxygen at all.

This commit fixes these comments. The generated doxygen documentation now
has proper docs for several classes and files, and the docs for the llvm
and llvm::detail namespaces are now empty.

Reviewed By: thakis, mizvekov

Differential Revision: https://reviews.llvm.org/D96736
2021-04-07 01:20:18 +02:00

378 lines
12 KiB
C++

//===- BinaryStreamArray.h - Array backed by an arbitrary stream *- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
///
/// \file
/// Lightweight arrays that are backed by an arbitrary BinaryStream. This file
/// provides two different array implementations.
///
/// VarStreamArray - Arrays of variable length records. The user specifies
/// an Extractor type that can extract a record from a given offset and
/// return the number of bytes consumed by the record.
///
/// FixedStreamArray - Arrays of fixed length records. This is similar in
/// spirit to ArrayRef<T>, but since it is backed by a BinaryStream, the
/// elements of the array need not be laid out in contiguous memory.
///
#ifndef LLVM_SUPPORT_BINARYSTREAMARRAY_H
#define LLVM_SUPPORT_BINARYSTREAMARRAY_H
#include "llvm/ADT/ArrayRef.h"
#include "llvm/ADT/iterator.h"
#include "llvm/Support/Alignment.h"
#include "llvm/Support/BinaryStreamRef.h"
#include "llvm/Support/Error.h"
#include <cassert>
#include <cstdint>
namespace llvm {
/// VarStreamArrayExtractor is intended to be specialized to provide customized
/// extraction logic. On input it receives a BinaryStreamRef pointing to the
/// beginning of the next record, but where the length of the record is not yet
/// known. Upon completion, it should return an appropriate Error instance if
/// a record could not be extracted, or if one could be extracted it should
/// return success and set Len to the number of bytes this record occupied in
/// the underlying stream, and it should fill out the fields of the value type
/// Item appropriately to represent the current record.
///
/// You can specialize this template for your own custom value types to avoid
/// having to specify a second template argument to VarStreamArray (documented
/// below).
template <typename T> struct VarStreamArrayExtractor {
// Method intentionally deleted. You must provide an explicit specialization
// with the following method implemented.
Error operator()(BinaryStreamRef Stream, uint32_t &Len,
T &Item) const = delete;
};
/// VarStreamArray represents an array of variable length records backed by a
/// stream. This could be a contiguous sequence of bytes in memory, it could
/// be a file on disk, or it could be a PDB stream where bytes are stored as
/// discontiguous blocks in a file. Usually it is desirable to treat arrays
/// as contiguous blocks of memory, but doing so with large PDB files, for
/// example, could mean allocating huge amounts of memory just to allow
/// re-ordering of stream data to be contiguous before iterating over it. By
/// abstracting this out, we need not duplicate this memory, and we can
/// iterate over arrays in arbitrarily formatted streams. Elements are parsed
/// lazily on iteration, so there is no upfront cost associated with building
/// or copying a VarStreamArray, no matter how large it may be.
///
/// You create a VarStreamArray by specifying a ValueType and an Extractor type.
/// If you do not specify an Extractor type, you are expected to specialize
/// VarStreamArrayExtractor<T> for your ValueType.
///
/// By default an Extractor is default constructed in the class, but in some
/// cases you might find it useful for an Extractor to maintain state across
/// extractions. In this case you can provide your own Extractor through a
/// secondary constructor. The following examples show various ways of
/// creating a VarStreamArray.
///
/// // Will use VarStreamArrayExtractor<MyType> as the extractor.
/// VarStreamArray<MyType> MyTypeArray;
///
/// // Will use a default-constructed MyExtractor as the extractor.
/// VarStreamArray<MyType, MyExtractor> MyTypeArray2;
///
/// // Will use the specific instance of MyExtractor provided.
/// // MyExtractor need not be default-constructible in this case.
/// MyExtractor E(SomeContext);
/// VarStreamArray<MyType, MyExtractor> MyTypeArray3(E);
///
template <typename ValueType, typename Extractor> class VarStreamArrayIterator;
template <typename ValueType,
typename Extractor = VarStreamArrayExtractor<ValueType>>
class VarStreamArray {
friend class VarStreamArrayIterator<ValueType, Extractor>;
public:
typedef VarStreamArrayIterator<ValueType, Extractor> Iterator;
VarStreamArray() = default;
explicit VarStreamArray(const Extractor &E) : E(E) {}
explicit VarStreamArray(BinaryStreamRef Stream, uint32_t Skew = 0)
: Stream(Stream), Skew(Skew) {}
VarStreamArray(BinaryStreamRef Stream, const Extractor &E, uint32_t Skew = 0)
: Stream(Stream), E(E), Skew(Skew) {}
Iterator begin(bool *HadError = nullptr) const {
return Iterator(*this, E, Skew, nullptr);
}
bool valid() const { return Stream.valid(); }
uint32_t skew() const { return Skew; }
Iterator end() const { return Iterator(E); }
bool empty() const { return Stream.getLength() == 0; }
VarStreamArray<ValueType, Extractor> substream(uint32_t Begin,
uint32_t End) const {
assert(Begin >= Skew);
// We should never cut off the beginning of the stream since it might be
// skewed, meaning the initial bytes are important.
BinaryStreamRef NewStream = Stream.slice(0, End);
return {NewStream, E, Begin};
}
/// given an offset into the array's underlying stream, return an
/// iterator to the record at that offset. This is considered unsafe
/// since the behavior is undefined if \p Offset does not refer to the
/// beginning of a valid record.
Iterator at(uint32_t Offset) const {
return Iterator(*this, E, Offset, nullptr);
}
const Extractor &getExtractor() const { return E; }
Extractor &getExtractor() { return E; }
BinaryStreamRef getUnderlyingStream() const { return Stream; }
void setUnderlyingStream(BinaryStreamRef NewStream, uint32_t NewSkew = 0) {
Stream = NewStream;
Skew = NewSkew;
}
void drop_front() { Skew += begin()->length(); }
private:
BinaryStreamRef Stream;
Extractor E;
uint32_t Skew = 0;
};
template <typename ValueType, typename Extractor>
class VarStreamArrayIterator
: public iterator_facade_base<VarStreamArrayIterator<ValueType, Extractor>,
std::forward_iterator_tag, ValueType> {
typedef VarStreamArrayIterator<ValueType, Extractor> IterType;
typedef VarStreamArray<ValueType, Extractor> ArrayType;
public:
VarStreamArrayIterator(const ArrayType &Array, const Extractor &E,
uint32_t Offset, bool *HadError)
: IterRef(Array.Stream.drop_front(Offset)), Extract(E),
Array(&Array), AbsOffset(Offset), HadError(HadError) {
if (IterRef.getLength() == 0)
moveToEnd();
else {
auto EC = Extract(IterRef, ThisLen, ThisValue);
if (EC) {
consumeError(std::move(EC));
markError();
}
}
}
VarStreamArrayIterator() = default;
explicit VarStreamArrayIterator(const Extractor &E) : Extract(E) {}
~VarStreamArrayIterator() = default;
bool operator==(const IterType &R) const {
if (Array && R.Array) {
// Both have a valid array, make sure they're same.
assert(Array == R.Array);
return IterRef == R.IterRef;
}
// Both iterators are at the end.
if (!Array && !R.Array)
return true;
// One is not at the end and one is.
return false;
}
const ValueType &operator*() const {
assert(Array && !HasError);
return ThisValue;
}
ValueType &operator*() {
assert(Array && !HasError);
return ThisValue;
}
IterType &operator+=(unsigned N) {
for (unsigned I = 0; I < N; ++I) {
// We are done with the current record, discard it so that we are
// positioned at the next record.
AbsOffset += ThisLen;
IterRef = IterRef.drop_front(ThisLen);
if (IterRef.getLength() == 0) {
// There is nothing after the current record, we must make this an end
// iterator.
moveToEnd();
} else {
// There is some data after the current record.
auto EC = Extract(IterRef, ThisLen, ThisValue);
if (EC) {
consumeError(std::move(EC));
markError();
} else if (ThisLen == 0) {
// An empty record? Make this an end iterator.
moveToEnd();
}
}
}
return *this;
}
uint32_t offset() const { return AbsOffset; }
uint32_t getRecordLength() const { return ThisLen; }
private:
void moveToEnd() {
Array = nullptr;
ThisLen = 0;
}
void markError() {
moveToEnd();
HasError = true;
if (HadError != nullptr)
*HadError = true;
}
ValueType ThisValue;
BinaryStreamRef IterRef;
Extractor Extract;
const ArrayType *Array{nullptr};
uint32_t ThisLen{0};
uint32_t AbsOffset{0};
bool HasError{false};
bool *HadError{nullptr};
};
template <typename T> class FixedStreamArrayIterator;
/// FixedStreamArray is similar to VarStreamArray, except with each record
/// having a fixed-length. As with VarStreamArray, there is no upfront
/// cost associated with building or copying a FixedStreamArray, as the
/// memory for each element is not read from the backing stream until that
/// element is iterated.
template <typename T> class FixedStreamArray {
friend class FixedStreamArrayIterator<T>;
public:
typedef FixedStreamArrayIterator<T> Iterator;
FixedStreamArray() = default;
explicit FixedStreamArray(BinaryStreamRef Stream) : Stream(Stream) {
assert(Stream.getLength() % sizeof(T) == 0);
}
bool operator==(const FixedStreamArray<T> &Other) const {
return Stream == Other.Stream;
}
bool operator!=(const FixedStreamArray<T> &Other) const {
return !(*this == Other);
}
FixedStreamArray(const FixedStreamArray &) = default;
FixedStreamArray &operator=(const FixedStreamArray &) = default;
const T &operator[](uint32_t Index) const {
assert(Index < size());
uint32_t Off = Index * sizeof(T);
ArrayRef<uint8_t> Data;
if (auto EC = Stream.readBytes(Off, sizeof(T), Data)) {
assert(false && "Unexpected failure reading from stream");
// This should never happen since we asserted that the stream length was
// an exact multiple of the element size.
consumeError(std::move(EC));
}
assert(isAddrAligned(Align::Of<T>(), Data.data()));
return *reinterpret_cast<const T *>(Data.data());
}
uint32_t size() const { return Stream.getLength() / sizeof(T); }
bool empty() const { return size() == 0; }
FixedStreamArrayIterator<T> begin() const {
return FixedStreamArrayIterator<T>(*this, 0);
}
FixedStreamArrayIterator<T> end() const {
return FixedStreamArrayIterator<T>(*this, size());
}
const T &front() const { return *begin(); }
const T &back() const {
FixedStreamArrayIterator<T> I = end();
return *(--I);
}
BinaryStreamRef getUnderlyingStream() const { return Stream; }
private:
BinaryStreamRef Stream;
};
template <typename T>
class FixedStreamArrayIterator
: public iterator_facade_base<FixedStreamArrayIterator<T>,
std::random_access_iterator_tag, const T> {
public:
FixedStreamArrayIterator(const FixedStreamArray<T> &Array, uint32_t Index)
: Array(Array), Index(Index) {}
FixedStreamArrayIterator<T>(const FixedStreamArrayIterator<T> &Other)
: Array(Other.Array), Index(Other.Index) {}
FixedStreamArrayIterator<T> &
operator=(const FixedStreamArrayIterator<T> &Other) {
Array = Other.Array;
Index = Other.Index;
return *this;
}
const T &operator*() const { return Array[Index]; }
const T &operator*() { return Array[Index]; }
bool operator==(const FixedStreamArrayIterator<T> &R) const {
assert(Array == R.Array);
return (Index == R.Index) && (Array == R.Array);
}
FixedStreamArrayIterator<T> &operator+=(std::ptrdiff_t N) {
Index += N;
return *this;
}
FixedStreamArrayIterator<T> &operator-=(std::ptrdiff_t N) {
assert(std::ptrdiff_t(Index) >= N);
Index -= N;
return *this;
}
std::ptrdiff_t operator-(const FixedStreamArrayIterator<T> &R) const {
assert(Array == R.Array);
assert(Index >= R.Index);
return Index - R.Index;
}
bool operator<(const FixedStreamArrayIterator<T> &RHS) const {
assert(Array == RHS.Array);
return Index < RHS.Index;
}
private:
FixedStreamArray<T> Array;
uint32_t Index;
};
} // namespace llvm
#endif // LLVM_SUPPORT_BINARYSTREAMARRAY_H